/* See LICENSE file for copyright and license details. */
#include "libred.h"
#include <math.h>
#include <time.h>
#include <errno.h>
#include <stdio.h>
#include <stdlib.h>
#if __GNUC__
# pragma GCC diagnostic push
# pragma GCC diagnostic ignored "-Wunsuffixed-float-constants"
#endif
/* Select clock. */
#if defined(DO_NOT_USE_COARSEC_CLOCK) || !defined(CLOCK_REALTIME_COARSE)
# ifdef CLOCK_REALTIME_COARSE
# undef CLOCK_REALTIME_COARSE
# endif
# define CLOCK_REALTIME_COARSE CLOCK_REALTIME
#endif
/**
* Get current Julian Centuries time (100 Julian days since J2000.)
*
* @return The current Julian Centuries time.
*
* @throws 0 On success.
* @throws Any error specified for clock_gettime(3) on error.
*/
static double
julian_centuries()
{
struct timespec now;
double tm;
if (clock_gettime(CLOCK_REALTIME_COARSE, &now))
return 0.0;
tm = (double)(now.tv_nsec) / 1000000000.0 + (double)(now.tv_sec);
tm = (tm / 86400.0 + 2440587.5 - 2451545.0) / 36525.0;
return errno = 0, tm;
}
/**
* Convert a Julian Centuries timestamp to a Julian Day timestamp.
*
* @param tm The time in Julian Centuries
* @return The time in Julian Days
*/
static inline double
julian_centuries_to_julian_day(double tm)
{
return tm * 36525.0 + 2451545.0;
}
/**
* Convert an angle (or otherwise) from degrees to radians.
*
* @param deg The angle in degrees.
* @param The angle in radians.
*/
static inline double
radians(double deg)
{
return deg * (double)M_PI / 180.0;
}
/**
* Convert an angle (or otherwise) from radians to degrees.
*
* @param rad The angle in radians.
* @param The angle in degrees.
*/
static inline double
degrees(double rad)
{
return rad * 180.0 / (double)M_PI;
}
/**
* Calculates the Sun's elevation from the solar hour angle
*
* @param longitude The longitude in degrees eastwards.
* from Greenwich, negative for westwards.
* @param declination The declination, in radians.
* @param hour_angle The solar hour angle, in radians.
* @return The Sun's elevation, in radians.
*/
static inline double
elevation_from_hour_angle(double latitude, double declination, double hour_angle)
{
double rc = cos(radians(latitude));
rc *= cos(hour_angle) * cos(declination);
rc += sin(radians(latitude)) * sin(declination);
return asin(rc);
}
/**
* Calculates the Sun's geometric mean longitude.
*
* @param tm The time in Julian Centuries.
* @return The Sun's geometric mean longitude in radians.
*/
static inline double
sun_geometric_mean_longitude(double tm)
{
double rc = fmod(pow(0.0003032 * tm, 2.0) + 36000.76983 * tm + 280.46646, 360.0);
#if defined(TIMETRAVELLER)
rc = rc < 0.0 ? (rc + 360.0) : rc;
#endif
return radians(rc);
}
/**
* Calculates the Sun's geometric mean anomaly.
*
* @param tm The time in Julian Centuries.
* @return The Sun's geometric mean anomaly in radians.
*/
static inline double
sun_geometric_mean_anomaly(double tm)
{
return radians(pow(-0.0001537 * tm, 2.0) + 35999.05029 * tm + 357.52911);
}
/**
* Calculates the Earth's orbit eccentricity.
*
* @param tm The time in Julian Centuries.
* @return The Earth's orbit eccentricity.
*/
static inline double
earth_orbit_eccentricity(double tm)
{
return pow(-0.0000001267 * tm, 2.0) - 0.000042037 * tm + 0.016708634;
}
/**
* Calculates the Sun's equation of the centre, the difference
* between the true anomaly and the mean anomaly.
*
* @param tm The time in Julian Centuries.
* @return The Sun's equation of the centre, in radians.
*/
static inline double
sun_equation_of_centre(double tm)
{
double a = sun_geometric_mean_anomaly(tm), rc;
rc = sin(1.0 * a) * (pow(-0.000014 * tm, 2.0) - 0.004817 * tm + 1.914602);
rc += sin(2.0 * a) * (-0.000101 * tm + 0.019993);
rc += sin(3.0 * a) * 0.000289;
return radians(rc);
}
/**
* Calculates the Sun's real longitudinal position.
*
* @param tm The time in Julian Centuries.
* @return The longitude, in radians.
*/
static inline double
sun_real_longitude(double tm)
{
return sun_geometric_mean_longitude(tm) + sun_equation_of_centre(tm);
}
/**
* Calculates the Sun's apparent longitudinal position.
*
* @param tm The time in Julian Centuries.
* @return The longitude, in radians.
*/
static inline double
sun_apparent_longitude(double tm)
{
double rc = degrees(sun_real_longitude(tm)) - 0.00569;
return radians(rc - 0.00478 * sin(radians(-1934.136 * tm + 125.04)));
}
/**
* Calculates the mean ecliptic obliquity of the Sun's
* apparent motion without variation correction.
*
* @param tm The time in Julian Centuries.
* @return The uncorrected mean obliquity, in radians.
*/
static double
mean_ecliptic_obliquity(double tm)
{
double rc = pow(0.001813 * tm, 3.0) - pow(0.00059 * tm, 2.0) - 46.815 * tm + 21.448;
return radians(23.0 + (26.0 + rc / 60.0) / 60.0);
}
/**
* Calculates the mean ecliptic obliquity of the Sun's
* parent motion with variation correction.
*
* @param tm The time in Julian Centuries.
* @return The mean obliquity, in radians.
*/
static double
corrected_mean_ecliptic_obliquity(double tm)
{
double rc = 0.00256 * cos(radians(-1934.136 * tm + 125.04));
return radians(rc + degrees(mean_ecliptic_obliquity(tm)));
}
/**
* Calculates the Sun's declination.
*
* @param tm The time in Julian Centuries.
* @return The Sun's declination, in radian.
*/
static inline double
solar_declination(double tm)
{
double rc = sin(corrected_mean_ecliptic_obliquity(tm));
return asin(rc * sin(sun_apparent_longitude(tm)));
}
/**
* Calculates the equation of time, the discrepancy
* between apparent and mean solar time.
*
* @param tm The time in Julian Centuries.
* @return The equation of time, in degrees.
*/
static inline double
equation_of_time(double tm)
{
double l = sun_geometric_mean_longitude(tm);
double e = earth_orbit_eccentricity(tm);
double m = sun_geometric_mean_anomaly(tm);
double y = pow(tan(corrected_mean_ecliptic_obliquity(tm) / 2.0), 2.0);
double rc = y * sin(2.0 * l);
rc += (4.0 * y * cos(2.0 * l) - 2.0) * e * sin(m);
rc -= pow(0.5 * y, 2.0) * sin(4.0 * l);
rc -= pow(1.25 * e, 2.0) * sin(2.0 * m);
return 4.0 * degrees(rc);
}
/**
* Calculates the Sun's elevation as apparent
* from a geographical position.
*
* @param tm The time in Julian Centuries.
* @param latitude The latitude in degrees northwards from
* the equator, negative for southwards.
* @param longitude The longitude in degrees eastwards from
* Greenwich, negative for westwards.
* @return The Sun's apparent elevation at the specified time as seen
* from the specified position, measured in radians.
*/
static inline double
solar_elevation_from_time(double tm, double latitude, double longitude)
{
double rc = julian_centuries_to_julian_day(tm);
rc = (rc - round(rc) - 0.5) * 1440;
rc = 720.0 - rc - equation_of_time(tm);
rc = radians(rc / 4.0 - longitude);
return elevation_from_hour_angle(latitude, solar_declination(tm), rc);
}
/**
* Calculates the Sun's elevation as apparent
* from a geographical position.
*
* @param latitude The latitude in degrees northwards from
* the equator, negative for southwards.
* @param longitude The longitude in degrees eastwards from
* Greenwich, negative for westwards.
* @return The Sun's apparent elevation as seen, right now,
* from the specified position, measured in degrees.
*
* @throws 0 On success.
* @throws Any error specified for clock_gettime(3) on error.
*/
double
libred_solar_elevation(double latitude, double longitude)
{
double tm = julian_centuries();
return errno ? -1 : degrees(solar_elevation_from_time(tm, latitude, longitude));
}
/**
* Exit if time the is before year 0 in J2000.
*
* @return 0 on success, -1 on error.
*/
int libred_check_timetravel(void)
{
#if !defined(TIMETRAVELLER)
struct timespec now;
if (clock_gettime(CLOCK_REALTIME, &now))
return -1;
if (now.tv_sec < (time_t)946728000L) {
fprintf(stderr,
"We have detected that you are a time-traveller"
"(or your clock is not configured correctly.)"
"Please recompile libred with -DTIMETRAVELLER"
"(or correct your clock.)");
exit(1);
}
#endif
return 0;
}
